Call for Paper - September 2022 Edition
IJCA solicits original research papers for the September 2022 Edition. Last date of manuscript submission is August 22, 2022. Read More

Designing and Implementation of Quantum Cellular Automata 2:1 Multiplexer Circuit

Print
PDF
International Journal of Computer Applications
© 2011 by IJCA Journal
Number 1 - Article 4
Year of Publication: 2011
Authors:
Debarka Mukhopadhyay
Sourav Dinda
Paramartha Dutta
10.5120/2996-4026

Debarka Mukhopadhyay, Sourav Dinda and Paramartha Dutta. Article: Designing and Implementation of Quantum Cellular Automata 2:1 Multiplexer Circuit. International Journal of Computer Applications 25(1):21-24, July 2011. Full text available. BibTeX

@article{key:article,
	author = {Debarka Mukhopadhyay and Sourav Dinda and Paramartha Dutta},
	title = {Article: Designing and Implementation of Quantum Cellular Automata 2:1 Multiplexer Circuit},
	journal = {International Journal of Computer Applications},
	year = {2011},
	volume = {25},
	number = {1},
	pages = {21-24},
	month = {July},
	note = {Full text available}
}

Abstract

Quantum Cellular Automata is a promising nanotechnology that has been recognized as one of the top six emerging technology in future computers. We have developed a new methodology in design QCA 2:1 MUX having better area efficiency and less input to output delay. We have also shown that using this QCA 2:1 MUX as a unit higher MUX can also be designed. We verified the proposed design using simulation from QCADesigner tool. This simulator is also useful for building complex QCA circuits.

Reference

  • A.O. Orlov, I. Amlani, G.H. Bernstein, C.S. Lent, G.L. Snider, Realization of a functional cell for quantum-dot cellular automata, Science 277 (1997) 928–930.
  • P.D. Tougaw, C.S. Lent, Logical devices implemented using quantum cellular automata, Journal of Applied Physics 75 (3) (1994) 1818–1825.
  • R. Farazkish, M.R. Azghadi, K. Navi, M. Haghparast, New method for decreasing the number of quantum dot cells in QCA circuits, World Applied Sciences Journal 6 (2008) 793–802.
  • T. Oya, T. Asai, T. Fukui, Y. Amemiya, A majority-logic device using an irreversible single-electron box, IEEE Transactions on Nanotechnology 2 (2003).
  • S. Amarel, G. Cooke, R.O. Winder, Majority gate network, IEEE Transactions Electronic Computers EC-13 (1964) 4–13.